Rational
Design of a Fluorescent Sensor to Simultaneously
Determine Both the Enantiomeric Composition and the Concentration
of Chiral Functional Amines
posted on 2015-04-08, 00:00authored byKaili Wen, Shanshan Yu, Zeng Huang, Liming Chen, Meng Xiao, Xiaoqi Yu, Lin Pu
A fluorescent
molecular probe, a 1,1′-bi-2-naphthol (BINOL)-based
bis(naphthylimine) compound (R)-4, is
designed to exhibit very different fluorescent responses at two emission
wavelengths toward a variety of chiral functional amines including
diamines, amino alcohols, and amino acids. At one emission wavelength
(λ1), it shows high sensitivity toward the substrates,
and at another wavelength (λ2), it shows high enantioselectivity.
This is the first rational design of such a dual responsive fluorescent
sensor which can be used to simultaneously determine both the concentration
and the enantiomeric composition of functional chiral amines by one
fluorescent measurement. This strategy is potentially generally applicable
for the construction of sensors for rapid assay of structurally diverse
chiral substrates. When (R)-4 is treated
with various chiral functional amines in the presence of Zn(OAc)2, its 2-naphthylamine units are displaced off to show large
fluorescent enhancement at λ1 = 427 nm (I1) due to the restored emission of 2-naphthylamine. The
combination of the remaining chiral binaphthyl unit with the chiral
substrates leads to highly enantioselective fluorescent enhancement
at λ2 > 500 nm (I2).
Since I1 is only concentration dependent
but independent of the chiral configuration, it allows the determination
of the substrate concentration. The highly enantioselective I2 allows the determination of the enantiomeric
composition. Thus, using one fluorescent probe with one fluorescent
measurement, both the concentration and the enantiomeric composition
are determined. The dual responsive mechanism of (R)-4 is studied by using various spectroscopic methods
including fluorescence, UV–vis, NMR, and mass analyses.